Energy Resources

1. Energy Resources Dharam Pal Sr. Lecturer Govt. Polytechnic,Manesar

2. Energy Resources • Supplementing free solar energy • 99% of heat comes from the sun • Without the sun, the earth would be –240 0C (-400 0F) • We supplement the other 1% with primarily non-renewable energy sources

3. Energy Resources • Renewable (16%) • Solar • Wind • Falling, flowing water • Biomass • Non-renewable (84%) • Oil • Natural gas • Coal • Nuclear power

4. Energy sources and uses • Energy uses in developed countries • industrial • domestic • transportation • Note: Electricity is not an energy source, converted from another source (coal, hydro, nuclear, etc.). • 1st Law of Thermodynamics - You can’t get more energy out of something than you put in • 2ond Law – In any conversion of heat energy to useful work, some energy is always degraded to a lower quality energy

5. Evaluating Energy Resources • Renewable • Future availability • Net energy yield • It takes energy to get energy • Habitat degradation • Cost (initial and ongoing) • Community disruption • Political or international issues • Suitability in different locations • Polluting (air, water, noise, visual)

6. Each type of power project needs to be evaluated for the benefits and costs

7. The environmental costs of hydroelectricity are much different than windpower, for example

8. Important Nonrenewable Energy Sources

9. North American Energy Resources US has only 2.4% of world’s oil reserves Average American uses in one day what a person in the poorest countries use in one year

10. OIL and NATURAL GAS • Accumulations of dead marine organisms on the ocean floor were covered by sediments. • Muddy rock gradually formed rock (shale) containing dispersed oil. • Sandstone formed on top of shale, thus oil pools began to form. • Natural gas often forms on top of oil. • Primary component of natural gas is methane

12. Based on boiling points Oil • Petroleum (crude oil) • Costs: • Recovery • Refining • Transporting • Environmental • Highest risks are in transportation • Refining yields many products • Asphalt • Heating oil • Diesel • Petrochemicals • Gasoline • …

13. Conventional Oil Advantages • Relatively low cost • High net energy yield • Efficient distribution system Disadvantages • Running out • 42-93 years • Low prices encourage waste • Air pollution and greenhouse gases • Water pollution

14. Arctic National Wildlife Refuge Controversy: Trade-offs • Would create jobs • Oil resources are uncertain • US supply 7-24 months • Uncertain environmental impacts

15. Oil Shale and Tar Sands Oil Shale: Oily rocks that contain a solid mix of hydro- carbons. Global supplies ~ 240 times conventional oil supplies. Tar Sand: Mixture of clay, sand water and bitumen - a thick and sticky heavy oil. Extracted by large electric shovels, mixed with hot water and steam to extract the bitumen. Bitumen heated to convert to synthetic crude oil.

16. Natural Gas • 50-90% methane • Cleanest of fossil fuels • Approximate 200 year supply • Advantages and disadvantages

17. Coal – What is it? • Solid fossil fuel formed in several stages • Land plants that lived 300-400 million years ago • Subjected to intense heat and pressure over many millions of years • Mostly carbon, small amounts of sulfur

18. Coal Formation and Types

19. Coal – what do we use it for? • Stages of coal formation • 300 million year old forests • peat > lignite > bituminous > anthracite • Primarily strip-mined • Used mostly for generating electricity • Used to generate 62% of the world’s electricity • Used to generate 52% of the U.S. electricity • Enough coal for about 200-1000 years • U.S. has 25% of world’s reserves • High environmental impact • Coal gasification and liquefaction

20. Coal: Trade-offs World’s most abundant fossil fuel Mining and burning coal has a severe environmental impact Accounts for over 1/3 of the world’s CO2 emissions

21. Nuclear Energy – What is it? • Anuclear change in which nuclei of certain isotopes with large mass numbers are split apart into lighter nuclei when struck by neutrons. • Nuclei – center of an atom, making up0 most of the atom’s mass • Isotopes – two or more forms of a chemical element that have the same number of protons but different mass numbers because they have different numbers of neutrons in their nuclei. • Neutron – elementary particle in all atoms. • Radioactivity – Unstable nuclei of atoms shoot out “chunks” of mass and energy.

22. Great danger of losing coolant! Nuclear Energy • Fission reactors • Uranium-235 • Fission • Resulting heat used to produce steam that spins turbines to generate electricity • Produces radioactive fission fragments Light water generator – used in all U.S. and 85% world wide.

23. Locations of U.S. Nuclear Power Plants

24. The Nuclear Fuel Cycle Produces highly radioactive materials that must be stored safely for 10,000-240,000 years.

25. Conventional Nuclear Power: Trade-offs No new plants in U.S. since 1978. All 120 plants ordered in 1973 have been cancelled. Cost over-runs High operating costs Three Mile Island Chernobyl

26. Three Mile Island - Pennsylvania • March 28, 1979 - Partial Core Melt-Down. • No Deaths. • Very Little Radiation Vented. • Public Relations Disaster.

27. Chernobyl – Ukraine (Former USSR) • April 26, 1986 • One of four reactors explodes. • 31 immediate deaths. • 116,000 people evacuated. • 24,000 evacuees received high doses of radiation. • Thyroid cancer in children. • Damaged reactor entombed in concrete, other reactors returned to service within months. • Eventually, remaining reactors out of service.

28. Dealing with Nuclear Waste • High- and low-level wastes • Terrorist threats – storage casks hold 5-10 X more ling-lived radioactivity than the nuclear power plant • Disposal proposals • Underground burial • Disposal in space (illegal under international law) • Burial in ice sheets (“ “) • Dumping into subduction zones (“ “) • Burial in ocean mud (“ “) • Conversion into harmless materials (no way to do this with current technology)

29. Yucca Mountain • In 1982, Congress called for a high-level radioactive disposal site to be selected by March 1987, and to be completed by 1998. • Final Site Selection Occurred in 1989. • Yucca Mountain, Nevada • Not to be completed before 2015. • Wastes stored and guarded in one place • Possible long-term groundwater contamination • Security and safety concerns during waste transport to the site • Critics contend it is safer to store wastes at existing nuclear power plants.

30. Permanent Underground Disposal of Nuclear Wastes Storage Containers Fuel rod Primary canister Ground Level Overpack container sealed Personnel elevator Unloaded from train Air shaft Nuclear waste shaft Underground Buried and capped Lowered down shaft

31. Low - Level Waste – (materials other than the radioactive isotopes) • Includes cooling water from nuclear reactors, material from decommissioned reactors, protective clothing, and like materials. • Prior to 1970, US alone placed 50,000 barrels of low-level radioactive waste on the ocean floor. • Moratorium in 1970, Ban in 1983.

32. Energy Efficiency and Renewable Energy • 84% of energy is wasted in the United States • 41% degradation (2ond law of Thermodynamics) • 43% unnecessary • Fuel wasting vehicles • Furnaces • Poorly insulated buildings • U.S. unnecessarily wastes 2/3 of the energy that the rest of the world’s population consumes!

33. Energy Efficiency and Renewable Energy • Four primary energy wasters: • Incandescent light bulb 95% • Nuclear Power – 86% • Cars – 75-80% • Coal – 66%

34. Energy Efficiencies – do more with less!

35. Ways to Improve Energy Efficiency • Cogeneration – combines heat and power • Two forms of energy (ex. steam and electricity) are provided from the same fuel source. Used in Western Europe, U.S. produces 9% of electricity using cogeneration plants) • Efficient electric motors • High-efficiency lighting • Increasing fuel economy • Alternative vehicles • Insulation • Plug leaks

36. Hybrid and Fuel Cell Cars • Hybrid cars still use traditional fossil fuels • Energy otherwise wasted charges battery which assists acceleration and hill climbing • More efficient than internal combustion engine alone, but still uses non-renewable resources • Fuel cell cars not yet available • Hydrogen gas is fuel • Very efficient • Low pollution • Major infrastructure change needed for fueling stations

37. Renewable energy sources • Solar • Flowing water • Wind • Biomass • Geothermal • Hydrogen

38. Using Solar Energy to Provide Heat Passive solar heating Active solar heating

39. Using Solar Energy to Provide High-Temperature Heat and Electricity • Solar thermal systems • Photovoltaic (PV) cells

40. Producing Electricity from Moving Water • Large-scale hydropower • Small-scale hydropower • Tidal power plant • Wave power plant

41. Producing Electricity from Wind

42. Producing Energy from Biomass • Biomass and biofuels • Biomass plantations • Crop residues • Animal manure • Biogas • Ethanol • Methanol

43. Geothermal Energy • Geothermal heat pumps • Geothermal exchange • Dry and wet steam • Hot water • Molten rock (magma) • Hot dry-rock zones

44. The Hydrogen Revolution • Environmentally friendly • Extracting hydrogen efficiently • Storing hydrogen • Fuel cells

45. Hydrogen Trade-offs

46. Entering the Age of Decentralized Micropower • Decentralized power systems • Micropower systems

47. Solutions: A Sustainable Energy Strategy

48. What Can You Do? Energy Use and Waste • Drive a car that gets at least 15 kilometers per liter (35 miles per gallon) and join a carpool. • Use mass transit, walking, and bicycling. • Super-insulate your house and plug all air leaks. • Turn off lights, TV sets, computers, and other electronic equipment when they are not in use. • Wash laundry in warm or cold water. • Use passive solar heating. • For cooling, open windows and use ceiling fans or whole-house attic or window fans. • Turn thermostats down in winter and up in summer. • Buy the most energy-efficient homes, lights, cars, and appliances available. • Turn down the thermostat on water heaters to 43-49ºC (110-120ºF) and insulate hot water heaters and pipes.